ELECTROMAGNETIC RELAY
An electromagnetic relay includes a fixed spring, a fixed contact configured to be swaged so as to be attached to the fixed spring, a movable spring, and a movable contact provided on the movable spring so as to be capable of making contact with the fixed contact, wherein a swaged portion of the fixed contact is formed so as not to protrude from a surface of the fixed spring.
This application is based on and claims priority to Japanese Patent Application No. 2017-224556, filed on Nov. 22, 2017, the entire contents of which are incorporated herein by reference.
BACKGROUND OF THE INVENTION 1. Field of the InventionThe present invention generally relates to an electromagnetic relay.
2. Description of the Related ArtA fixed contact is swaged so as to be attached to a fixed spring of an electromagnetic relay. When the contact is swaged to the fixed spring, the pressed end of the contact protrudes from the surface of the fixed spring.
In the conventional method of swaging a contact, although coupling strength is high, there is a possibility that a portion protruding from the fixed spring may be brought into contact with a molded part such as a bobbin. If the protruding portion contacts with the bobbin, the bobbin may be chipped and the chipped pieces may be interposed between contacts, which may cause conduction failure. Further, if the protruding portion contacts with the bobbin, the bobbin or the fixed spring may be deformed. As a result, assembly dimensions may deviate from design values, resulting in a decrease. in a non-adjustment rate and an increase in a failure rate. If a structure for avoiding contact between the protruding portion of the contact and the bobbin is provided, it may decrease the strength of the bobbin or may hinder downsizing of the bobbin*.
RELATED-ART DOCUMENTS Patent Documents
- [Patent Document 1] Japanese Unexamined Patent Application Publication No. 9-97550
It is a general object of an embodiment of the present invention to provide an electromagnetic relay that can prevent a fixed contact from interfering with other parts.
According to at least one embodiment, an electromagnetic relay includes a fixed spring, a fixed contact configured to be swaged so as to be attached to the fixed spring, a movable spring, and a movable contact provided on the movable spring so as to be capable of making contact with the fixed contact, wherein a swaged portion of the fixed contact is formed so as not to protrude from a surface of the fixed spring.
Other objects and further features of the present invention will be apparent from the following detailed description when read in conjunction with the accompanying drawings.
According to at least one embodiment, an electromagnetic relay that can prevent a fixed contact from interfering with other parts can be provided.
In the following, embodiments of the present invention will be described with reference to the accompanying drawings. In the drawings, the same elements are denoted by the same reference numerals, and a duplicate description thereof will be omitted.
In the following, three axes (x-axis, y-axis, and z-axis) that are perpendicular to each other are used as references to describe shapes and positional relationships of components of the electromagnetic relay 50. As illustrated in
For example, the electromagnetic relay 50 according to the present embodiment is used for a vehicle in which a 12V DC battery or a 24V DC battery is installed, or is used for a mild hybrid vehicle in which a 48V DC battery is installed. To be more specific, the electromagnetic relay 50 is used for switching control of a control circuit of a 12V DC battery, a 24V DC battery, or a 48V DC battery.
The electromagnetic relay 50 illustrated in
The base 1 is made of an electrically-insulating resin, and includes a rectangular frame 10 and a bottom 11 that closes the bottom side of the frame 10. The base 1 has a recessed portion 12 that is defined by the frame 10 and the bottom 11 and opens upward. The electromagnet 2 and the contact 3 are fixedly supported by the recessed portion 12. The cover 4 is adhesively fixed to the frame 10.
The electromagnet 2 includes a hollow body 20g extending along the z-axis, a spool 20 including an upper flange 20a located at the top of the spool 20 and a lower flange 20b located at the bottom of the spool 20, an iron core 21 housed in the body 20g, and a coil 22 provided on the outer surface of the spool 20. The lower flange 20b is fixedly supported by the recessed portion 12.
A stepped portion 20c is formed at the center of the upper flange 20a. A narrow portion 20h having a width narrower than that of the upper flange 20a along the y-axis is provided on the front side of the stepped portion 20c. Right and left side walls 20d is raised upward from the narrow portion 20h. Above the front end of the upper flange 20a, an upper wall 20e parallel to the upper flange 20a is provided between two side walls 20d. A box-shaped space SP with the front and back sides being open is formed by the upper flange 20a, side walls 20d, and upper wall 20e. At the upper end of the right side wall 20d, a slit 20f is formed from the front towards the back to be parallel to the upper wall 20e. The slit 20f is used to mount the break spring 33, which will be described later.
The iron core 21 is a columnar member formed of magnetic steel, for example. An upper end surface 21a of the iron core 21 is exposed to the outside from the upper flange 20a while the iron core 21 is housed in the spool. The part of the iron core 21 other than the end surface 21a is fixedly supported inside the body 20g. The wire of the coil 22 is wound around the outer surface of the body 20g between the upper flange 20a and the lower flange 20b. Each end of the coil 22 is connected to corresponding one of coil terminals 23 fixed to the base 1. A yoke 24 is fixedly connected to the lower end of the iron core 21 by, for example, swaging.
The yoke 24 is a plate-shaped member formed by die-cutting and bending a magnetic steel sheet into an L-shape in cross section, for example. In a state in which the electromagnetic relay 50 is assembled, the yoke 24 extends below the lower flange 20b along the x-axis and extends behind the body 20g along the z-axis. An upper end 24a of the yoke 24 is located at approximately the same height as the end surface 21a.
An armature 25 is a flat plate-shaped member formed by die-cutting a magnetic steel sheet, for example. In an assembled state as illustrated in
The armature 25 is attached to the movable spring 26, and is resiliently and relatively-movably coupled to the yoke 24 via the movable spring 26. The movable spring 26 is formed by die-cutting and bending a thin sheet formed of phosphor bronze for springs into an approximately L-shape. As illustrated in
The movable spring 26 functions as a hinge that elastically connects the yoke 24 and the armature 25, and biases the armature 25 in a direction away from the end surface 21a by means of the spring force of the hinge springs 26c. The movable contacts 30 are attached to the respective tips of the arms 26d by, for example, swaging. The arms 26d are inserted into the space SP between the upper wall 20e and the upper flange 20a from the back side. The movable contacts 30 are disposed in the space SP so as to be capable of making contact with the make contacts 34 and the break contacts 35, which will be described later.
The right and left ends of the vertical portion 26a form terminals 31b that are bent frontward at approximately a right angle and extend downward. The terminals 31b are disposed at the right and left rear corners of the recessed portion 12, and penetrate the bottom 11 of the base 1.
The make spring 32 is formed by die-cutting and bending a copper sheet, for example. As illustrated in
The horizontal portions 32b are inserted into the space SP from the front side of the spool 20. As illustrated in
The break spring 33 is formed by die-cutting and bending a copper sheet, for example. The break spring 33 integrally includes a horizontal portion 33a that extends along the y-axis and the terminal 33b that is bent downward from the right end of the horizontal portion 33a at approximately a right angle.
In the assembled state as illustrated in
In the assembled state as illustrated in
For example, the electromagnetic relay 50 is operated as follows. When voltage is not applied to the coil 22, the movable spring 26 biases the armature 25 in a direction away from the movable spring 26. Accordingly, the movable contacts 30 are held at a non-operating position away from the make contacts 34 while making contact with the break contacts 35 (see
Conversely, when voltage is applied to the coil 22, magnetic attractive force of the electromagnet 2 attracts the armature 25 toward the upper surface 21a against the spring force of the movable spring 26, and the movable contacts 30 move downward. Accordingly, the movable contacts 30 make contact with the make contacts 34. Also, the movable contacts 30 are stationarily held at an operating position.
Because contact pairs of the movable contacts 30 and make contacts 34 are provided at the right and left, a parallel circuit is formed between the two contact pairs when the electromagnet 2 is operated. Accordingly, an electric current is branched and flows through each of the two contact pairs.
Next referring to
As illustrated in
The upper surface of the horizontal portion 33a, namely the surface on which the break contacts 35 are swaged, has recesses 33d in the holes 33c. The recesses 33d are each formed in a stepped shape around the entire outer edge of the upper side of the corresponding hole 33c. The recesses 33d are concentric with the holes 33c, and a diameter of the recesses 33d is larger than a diameter of the holes 33c.
When the break contacts 35 are swaged to the holes 33c having the above-described shape, swaged portions 35a are each formed so as to extend into the corresponding recess 33d as illustrated in
As illustrated in
The lower surfaces of the horizontal portions 32b, namely the surfaces on which the make contacts 34 are swaged, have recesses 32e in the holes 32d. The recesses 32e are each formed in a stepped shape around the entire outer edge of the lower side of the horizontal portions 32b. The recesses 32e are concentric with the holes 32d, and a diameter of the recesses 32e is larger than a diameter of the holes 32d.
When the make contacts 34 are swaged to the holes 32d having the above-described shape, swaged portions 34a are each formed so as to extend into the corresponding recess 32e as illustrated in
As described, the swaged portions 35a are formed so as not to protrude from the upper surface of the horizontal portion 33a. Accordingly, when the contact 3 is fitted to the electromagnet 2, the swaged portions 35a do not readily make contact with the lower surface of the upper wall 20e. Therefore, as illustrated in
Similarly, the swaged portions 34a are formed so as not to protrude from the lower surfaces of the horizontal portions 32b. Accordingly, when the contact 3 is fitted to the electromagnet 2, the swaged portions 34a do not readily make contact with the upper surface of the narrow portion 20h. Therefore, as illustrated in
By making the upper wall 20e and the narrow portion 20h flat, the thickness of the upper wall 20e and the thickness of the narrow portion 20h can be made uniform when the upper wall 20e and the narrow portion 20h are molded. Accordingly, moldability and strength of the spool 20 can be expected to improve.
Further, the swaged portions 34a and 35a are formed so as not to protrude from the break spring 33 and the make spring 32, allowing the surfaces of the break spring 33 and the make spring to be made flat. Accordingly, when the fixed springs 32 and 33, whose fixed contacts 34 and 35 have been swaged, are press-fitted to the spool 20, the make contacts 34 and the break contacts 35 can be prevented from interfering with the spool 20, and thus, wear and chipping of parts can be reduced. Accordingly, it is possible to prevent a foreign material due to wear and chipping from entering the electromagnetic relay 50, and thus reduce malfunction caused by the foreign material. Also, by preventing the parts from interfering with each other, it is possible to reduce malfunction due to assembly failure. Such malfunction occurs, for example, when the fixed springs are forcibly press-fitted to the spool 20, causing the spool 20 or the fixed springs to be deformed.
It should be noted that, even when the electromagnetic relay 50 has a different internal configuration from that of the present embodiment, namely even when the swaged portions of the make contacts 34 and the break contacts 35 are positioned so as to face parts other than the spool 20, the make contacts 34 and the break contacts 35 can be prevented from interfering with the parts by attaching the make contacts 34 and the break contacts 35 in the same way as the present embodiment. Accordingly, a similar effect to that of the present embodiment can be exhibited.
Also, according to the present embodiment, a stepped recess is formed in a hole such that a portion of a fixed contact extends into the stepped recess and becomes parallel to the surface of a horizontal portion. Thus, coupling strength does not decrease as compared to a method of swaging a fixed contact to a hole without a recess.
Shortening the fixed contact can result in material savings. Also, providing the stepped recess can increase the area of the fixed contact making contact with the fixed spring. Accordingly, it is possible to reduce heat generation and improve strength.
As a comparative example, a hole without a recess will be described below.
As illustrated in
In this case, when the contact 3 is fitted to the electromagnet 2, the swaged portions 135a tend to make contact with the bottom surface of the upper wall 20e. Therefore, the break contacts 135 tend to interfere with the spool 20. As illustrated in
Similarly, when the contact 3 is fitted to the electromagnet 2, the swaged portions 34a tend to make contact with the upper surface of a narrow portion 20. Therefore, the make contacts 34 tend to interfere with the spool 20. As illustrated in
When the spool 20 has the grooves 120 and 121, the thickness of the upper wall 20e and the thickness of the narrow portion 20h do not become uniform. Thus, moldability and strength of the spool may decrease. Conversely, in the present embodiment, as described with reference to
Referring to
Further, the recesses may have a tapered shape in cross section. The recesses are not required to be formed in a stepped shape as in the case of the recesses 32e and 33d illustrated in
Although the embodiments have been specifically described above, the present disclosure is not limited to the above-described embodiments. These specific embodiments may be modified by a person skilled in the art as long as the features of the present disclosure are included. Elements and their arrangement, conditions, and shapes are not limited to the above-described embodiments and may be modified as necessary. It should be noted that combination of the elements of the above-described embodiments may be changed as long as no technical contradiction occurs.
Further, the electromagnetic relay 50 may have internal configurations other than those of the above-described embodiments.
In the above-described embodiments, the number of the movable contacts and of the fixed contacts is 2. However, the number of movable contacts and of the fixed contacts may be 1 or may be 3 or more.
In the above-described embodiments, both the make spring 32 and the break spring 33 have the recesses, such that both the swaged portions 34a and 35a do not protrude. Alternatively, either one of the make contacts 34 and the break contacts 35 may have recesses. In the electromagnetic relay 50 according to the embodiment illustrated in
Claims
1. An electromagnetic relay comprising:
- a fixed spring;
- a fixed contact configured to be swaged so as to be attached to the fixed spring;
- a movable spring; and
- a movable contact provided on the movable spring so as to be capable of making contact with the fixed contact,
- wherein a swaged portion of the fixed contact is formed so as not to protrude from a surface of the fixed spring.
2. The electromagnetic relay according to claim 1, wherein the surface of the fixed spring on which the swaged portion is formed has a recess at an outer edge of the hole, and the swaged portion is formed in the recess.
3. The electromagnetic relay according to claim 1, wherein
- a contact of the electromagnetic relay is a transfer contact,
- the fixed spring includes a make spring and a break spring,
- the fixed contact includes a make contact provided on the make spring and a break contact provided on the break spring, and
- a swaged portion of at least one of the make contact and the break contact is formed so as not to protrude from a surface of the corresponding spring.
Type: Application
Filed: Oct 30, 2018
Publication Date: May 23, 2019
Patent Grant number: 11043347
Inventors: Takaki Sunohara (Tokyo), Nobuyoshi Hiraiwa (Tokyo)
Application Number: 16/174,872